Guideless resilient androgynous serial port docking mechanism

ABSTRACT

The Guideless Resilient Androgynous Serial Port (GRASP) mechanism provides an androgynous mechanical and electrical interface that can be tailored to the meet the requirements of a given application. Each mechanism is equipped with physical connections (spring pins) for both power and data transmission between modules.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a Continuation of U.S. application Ser. No.16/740,546 filed Jan. 13, 2020, which claims priority to US ProvisionalApplication 62/791,918 filed Jan. 14, 2019, both of which are herebyincorporated herein by reference.

GOVERNMENT CONTRACT

The invention was made with government support with United StatesGovernment Agency, Defense Advanced Research Projects Agency underContracts D16PC00182 and D17PC00307. The Government has certain rightsin the invention.

BACKGROUND OF THE INVENTION

Modular spacecraft concepts provide a unique challenge for docking portdesign, requiring an androgynous, retractable docking port with at least90° rotational symmetry to enable multiple docking orientations, whilesupplying physical connections for both data and power transmission. Inorder to enable docking in more than two orientations, early USIP designconcepts required a combination of linear and rotary actuators whichoccupy a sizeable volume and increase complexity by adding a degree offreedom to the docking system, which will need to be restrained tosecure the dock.

The DARPA SYNERGEO Phase I effort (contract #D16PC00182) to develop afunctional docking interface design started with the existing conceptsand a literature search for past spacecraft docking port designs. Untilthe turn of the century, spacecraft docking port design was focused onhuman-rated technology to enable missions to orbiting research andobservation platforms such as Spacelab, MIR and the ISS. Thisinformation provided some useful insight into the various strategies forspacecraft approach and docking, and the underlying technologies thatenable these large, retractable and androgynous docking solutionsprovided a useful starting reference for the development of the GRASP.Shifting focus to the realm of small satellites, there have been someinteresting developments in the last 15 years, but domestic efforts havelargely eschewed androgyny and the ability to retract in favor ofemulating the classical probe-drogue port design, which is time-testedand proven in both space and atmosphere. Publicly available informationon recent domestic developments include the non-androgynous MechanicalDocking System used on Orbital Express, the SPHERES androgynous butasymmetric Universal Docking Port (UDP) demonstrated successfully on theISS, the Autonomous Satellite Docking System (ASDS) developed anddemonstrated by Michigan Aerospace, the AMODS electro-magnetic dockingsystem under development at the US Naval Academy, and Velcro pads, whichare non-androgynous and unreliable in structural applications.

All these docking ports fail to meet SYNERGEO requirements for symmetricandrogyny. International efforts in the realm of small satellite dockingports have yielded several concepts; two of the relevant concepts are asemi-androgynous docking interface under development at the Universityof Padova, Italy, and the port utilized in the German iBOSS effort,which is a potential option for the modular spacecraft concept. The portunder development at University of Padova is an innovative concept thatcan switch between probe and drogue functions as needed and uses acentral spring-loaded plunger to supply the force necessary to maintainsecure docking.

SUMMARY OF THE INVENTION

The Guideless Resilient Androgynous Serial Port (GRASP) mechanismprovides an androgynous mechanical and electrical interface that can betailored to the meet the requirements of a given application. Developedunder the DARPA SYNERGEO program (Phase I #D16PC00182 and Phase II#D17PC00307), assembly interfaces comprised of a multi-GRASP array and asingle mechanism have been developed. Each mechanism is equipped withphysical connections (spring pins) for both power and data transmissionbetween modules.

Numerous other advantages and features of the invention will becomereadily apparent from the following detailed description of theinvention and the embodiments thereof, from the claims, and from theaccompanying drawings.

BRIEF DESCRIPTION OF THE FIGURES

The patent or application file contains at least one drawing executed incolor. Copies of this patent or patent application publication withcolor drawing(s) will be provided by the Office upon request and paymentof the necessary fee. A fuller understanding of the foregoing may be hadby reference to the accompanying drawings, wherein:

FIG. 1 is a test apparatus equipped with four Generic ResilientAndrogynous Serial Port (GRASP) v1 prototypes (corners), this apparatusis used to demonstrate a multi-point GRASP interface that exhibits 90°rotational symmetry normal to the contact plane;

FIGS. 2A-2B illustrate a multi-point (2A) and single-point (2B) GRASPinterface concepts, the GRASP spring pin arrays are designed to enableconnections between identical mechanisms;

FIG. 3 illustrates the multi-point GRASP array designed for SYNERGEO,which allows a pair of module interfaces to mate successfully in fourorientations, each established by rotating one of the two bodies by 90°about the +z axis of its interface. In the example above, the passivebody is held stationary while the active is rotated;

FIGS. 4A-4D are illustrations of a GRASP breadboard prototype;

FIG. 5 is an exploded view of the GRASP breadboard prototype equippedwith an integrated ratchet;

FIGS. 6A-6C are illustrated views of the GRASP breadboard prototype,shown in the ‘active’ configuration (docking screw fully extended); thisfirst prototype is equipped with a ratchet to enable androgyny, with theteeth integrated into the docking nut.

FIG. 7 illustrates GRASP breadboard prototypes; the mechanism to theleft integrates a ratchet into the docking nut, while the mechanism tothe right uses a needle roller clutch to achieve the desired one-wayfreewheel behavior.

FIG. 8 is a GRASP v1 prototype illustration;

FIGS. 9A-9C are detailed view of the GRASP v1 prototype, shown in the‘passive’ configuration (docking screw fully retracted); this prototypeuses a needle roller clutch to enable androgyny.

FIGS. 10A-10D show the docking process between two GRASP mechanisms,shown in 4 steps; the active mechanism is denoted by A, while B is thepassive mechanism.

FIG. 11 illustrate a GRASP v2 mechanism contact surface features.

FIG. 12 illustrates a conceptual GRASP v2 drivetrain arrangement (CONOPSsensor package not shown); and

FIGS. 13A-13D show detailed views of the GRASP v2 prototype, to be usedfor the SYNERGEO single-point GRASP interface, shown in the ‘active’configuration (docking screw fully extended); this prototype uses aneedle roller clutch to enable androgyny.

DESCRIPTION OF THE INVENTION

The apparatuses shown in FIGS. 1 and 2A are an equally-spaced array of 4GRASP v1 mechanisms 100 mounted to a structural plate 50 built tosimulate a face of a SYNERGEO spacecraft, with a single GRASP mechanismwith a four-point connection in FIG. 2B. The array includes powerconnections rated for 360 A power transmission (90 A per mechanism) and20 discrete pairs of low-power connections for data transmission. Thelarge number of low-power pins enable a tailored approach tocommunications from module to module and throughout the modularspacecraft platform based on payload requirements for security,bandwidth, or noise. Secure mating between modules equipped with a4-point interface can be accomplished using as few as two diagonallyopposed mechanisms, providing a high level of redundancy in comparisonto existing solutions.

Note that 90° rotational symmetry at the interface, illustrated in FIG.3, is a requirement for SYNERGEO that has been satisfied with both amulti-GRASP array and a single GRASP mechanism. FIG. 3 shows themulti-point GRASP array designed for SYNERGEO, which allows a pair ofmodule interfaces to mate successfully in four orientations, eachestablished by rotating one of the two bodies by 90° about the +z axisof its interface. In the example above, the passive body is heldstationary while the active is rotated. The modular and customizablefeatures of the GRASP mechanism 100 and interface concept provide thespacecraft builder a variety of approaches to satisfying structural,electrical, and morphological constraints particular to a givenapplication.

At a fundamental level, the GRASP mechanism 100 provides a mechanicalconnection through a bolted joint. The novelty of GRASP is the androgynyof the mechanism; a GRASP in the ‘passive’ configuration, FIGS. 4A-4D,has the docking screw fully retracted and acts as the nut, while a GRASPin the ‘active’ configuration, FIGS. 6A-6C, has the docking screw fullyextended and acts as the bolt. This androgyny is made possible byallowing the docking nut to rotate (freewheel) about its cylindricalaxis in only one direction.

As provided in greater detail for FIGS. 4A-6C, the GRASP mechanism 100has a base plate 105 having an outward facing surface 107 that wouldserve as the connection surface to another GRASP mechanism. The baseplate 105 also has an inward facing surface 109. The base plate 105 hasnumerous channels bored through to service as conduits 110 for thevarious supplies or signals, power, water, electrical, data etc. Theseinclude various spring pins and pin targets 116, some of which may bereferred to commonly as pogo pins used in electrical connectorapplications. An array 115 of these pins would be connected on theinward facing surface 109 over the conduits 110 and extend to theconnection surface such that when two GRASP mechanisms were connected afull signal and supply connection would be made (the various conduittubing connecting to the array is not shown). Multiple arrays may beemployed as needed or required by design.

The GRASP mechanism 100 has a housing unit 120 secured to the base plate105 over an opening 125 defined in the base plate 105. The outwardfacing surface 107 may also include an indented surface 130 surroundingthe opening 125 to assist in the alignment. The indented surface 130 mayhave a cylindrical outer wall profile or it may be tapered in atruncated cone (FIG. 9) towards the opening 125 to help guide thedocking screw into the opening. The housing unit 120 is defined by alower housing 135 that is either secured to the inward facing surface109 of the base plate 105 or the lower housing 135 may be molded withthe base plate 105 as a single unitary structure. The lower housing 135includes a lip 140 surrounding the opening 125 with a ridge 142extending to a circular surface wall 144. Adjacent a portion of thecircular surface wall 144 is a channel cut out 146.

Positioned against the ridge 142 and over the opening 125 is a dockingnut 150. The docking nut 150 has a body portion 152 that includes athreaded interior surface 154 with an exterior lower ratchet toothedsection 156. The exterior lower ratchet toothed section 156 rotatablysits against the ridge 142 within the circular surface wall 144. A pawl160 and spring 162 are positioned by a pawl pin 163 in the channel cutout 146 to engage the ratchet toothed section allowing rotation of thedocking nut 150 in only a single direction. A docking screw 165 isthreaded into the docking nut 150.

Secured to the lower housing is an upper housing 170 used to secure thedocking nut and pawl in position. The upper housing 170 includes a bore172 sized to receive the docking screw and the body portion 152 of thedocking nut 150.

The docking screw 165 has an interior channel 167 keyed to receive aprofiled driveshaft 180 that when inserted and rotated in eitherdirection will rotate the docking screw 165. The docking screw 165 mayfurther have an extended flat top or dog end 169 used to locate into thedocking nut of the other mechanism during connection.

The driveshaft 180 is meshed to a main gear 185 further meshed to spurgear(s) 187 and driven by a motor 190. The top 182 of the drive shaft180 is rotatably positioned against a bearing 184 mounted to a mountingplate 192. Posts 195 are secured between the mounting plate 192 and thebase plate 105 to secure the mounting plate to the base plate with themotor 190 mounted between the two plates as well.

A variety of existing technologies, (e.g. ratchet, one-way bearing,sprag clutch), can be used in the GRASP mechanism to achieve thisone-way freewheel motion. The GRASP breadboard mechanism 100 shown inFIGS. 4-7 implements a simple ratchet with teeth integrated into thedocking nut and a pawl mounted to the mechanism base plate. Anotheriteration 200, shown on the right of FIG. 7, replaced the ratchet teethand pawl of the GRASP 100 mechanism with a flange, and used a one-waybearing known (needle roller clutch) to achieve the desired rotationallimit. This approach is applied to the GRASP v1 prototype, FIGS. 8-9C,and in the single-point GRASP interface depicted in FIGS. 11-13.

Referring now to FIG. 9A-9C the GRASP mechanism 200 is designedsimilarly to the GRASP mechanism 100, but as mentioned employs a needleroller clutch 205 to restrict rotation of the docking nut to a singledirection.

Docking screw motion in the v1 and v2 prototypes is powered by a COTSbrushless DC micro-motor (“BLDC motor”) which transmits torque to thedriveshaft via a parallel-output transmission. The motor is sized toprovide the torque required at the driveshaft to generate the mechanicalpreload required by the application and maintain sufficient margin. Avariety of sensors and mechanism monitoring strategies are used tomonitor performance during actuation and verify that joint mechanicalpreload requirements have been met.

The docking process between two GRASP breadboard mechanisms,representing one ‘corner’ of the 4-point SYNERGEO interface, is shown inFIGS. 10A-10D. Due to the androgynous design of the docking mechanism,either module can be assigned the active role in the operation. In thisseries of images, the active port is designated by 100A or A, while 100Bor B is the passive port.

In the first step, APPROACH, a servicing spacecraft will use its roboticmanipulators to present the incoming module for docking to the platformin a predetermined orientation, ensuring the correct docking ports arealigned.

In step 2, the motor of active port A will activate, advancing itsdocking screw such that it threads through the ratchet nut until thehead of the docking screw contacts the ratchet nut, after which theratchet nut will freewheel and the docking screw with the nut will thencontinue to turn clockwise. In the various embodiments of the mechanismsdiscussed herein, the docking screw during its initial rotations withrotate through a stationary docking nut. When the docking screw is fullyextending through the docking nut and the head of the screw comes intocontact with the docking nut, continuous rotation of the docking screwcauses a torque on the docking nut such that the nut will begin to turnwith the rotation of the screw. In the embodiment of the ratchet/pawl,the teeth and pawl are configured to prevent rotation in one directionbut allow slippage when the torque from the screw is pressed into thenut and rotation is continued. In the embodiment of the needle rollerclutch it is the configuration of the clutch to prevent rotation in onedirection and allow rotational slippage to avoid over-torqueing. Thesework perfectly in the current GRASP mechanisms.

During the third step, ALIGN, the tip of the mechanism A docking screwwill be protruding from the side of the spacecraft, and the screw+nutcombination will continue to freely rotate clockwise as the tip of thedocking screw is brought into contact with the mechanism B alignmentcone. The tip of the screw will traverse the mechanism B alignment cone,correcting any misalignment between the mechanisms so docking screw Aengages the threads in the mechanism B ratchet sleeve. During conetraversal, the rotating motion of the screw tip helps reduce contactfriction at the screw/alignment cone interface.

Once aligned, the continuously rotating docking screw+nut combination ofmechanism A will engage the threads of the mechanism B docking nut, andthe torque provided by the motor actuating mechanism A will tighten thebolted joint and end when the target interface preload is achieved. Itis during this step that power and data connections are made.

The transition of the spacecraft module design from a multi-point designper spacecraft side to a single-point GRASP interface has yieldedseveral benefits beyond the cost savings associated with electronics.Chief among them is a reduction in risk via elimination of 3 mechanismsper face, along with their associated potential failure modes. Duringthis transition, the results of a concurrent platform networking modulethe selection of Gigabit Ethernet as the default inter/intra-modularnetworking solution, which reduced the GRASP-specific conductor countfor a six-port module from >1000 to <400 (estimated; includes wires forspring pin array, motor control and CONOPS sensor package). Thedifference between the v1 prototype mechanism used for early testing andthe GRASP v2 concept is illustrated in FIG. 2.

The single-point concept meets the 90° rotational symmetry requirementand provides fine alignment during docking using a static array ofconventional probe+cone alignment features. While the static alignmentprobes have the potential to shrink the available volume for thespacecraft modules, the mass and complexity savings of moving to asingle-point interface prove an acceptable trade.

During exploration of the single-point concept, it was determined in analternative embodiment to provide a GRASP mechanism with modular springpin arrays so that the electrical interface can be updated as thestation architecture concept evolves.

In FIGS. 11-13D, designs of a GRASP mechanism 300 are shown, with amplespace available for the spring pin array interposers. FIG. 11 depicts acontact surface of the interface with screw extended, while FIG. 12illustrates the drivetrain and an early mounting bracket, designed topreserve alignment between the driveshaft and the docking screwthroughout the range of travel.

As illustrated the GRASP mechanism 300 has an X shaped base plate 305having an outward facing surface 306 that would serve as the connectionor contact surface to another GRASP mechanism. The base plate 305 alsohas an inward facing surface 309. The base plate 305 has an alignmentprobe 307 with corresponding alignment cones 310 that help align twoGRASP mechanisms. The probes 307 when approaching the alignment cones ona second GRASP mechanism will ride the cones to the center aligning thetwo mechanisms together.

The GRASP mechanism 300 has one way bearing mount 320 secured to thebase plate 305 over an opening 325 defined in the base plate 305. Theoutward facing surface 307 may also include an indented surface 330surrounding the opening 325 to assist in the alignment. The indentedsurface 330 may have a cylindrical outer wall profile or it may betapered in a truncated cone 327 towards the opening 325 to help guidethe docking screw into the opening. The one-way bearing mount 320 housesthe needle roller clutch 330 and the docking nut 350. As noted above,the docking nut 350 has a body portion that includes a threaded interiorsurface. A docking screw 360 is threaded into the docking nut 350.

The docking screw 360 has an interior channel 365 keyed to receive aprofiled driveshaft 380 that when inserted and rotated by an outputshaft 382 3 in either direction will rotate the docking screw 360. Thedocking screw 360 may further have an extended flat top or dog end 367used to locate into the docking nut of the other mechanism duringconnection.

The driveshaft 380 is controlled by a BLDC motor 385 with a paralleloutput transmission 390 and field director 395. Posts 397 are securedbetween the base plate 305 and the transmission housing. Lastly, thebase plate 305 includes interface mounts 308 permitting the GRASPmechanism 300 to be secured to a surface of a spacecraft.

As defined by the drawings herein, there is provided a first GRASPmechanism for a spacecraft docking system and for use with a secondGRASP mechanism similarly configured. Each of the GRASP mechanismsinclude:

(a) a base plate having an opening bored through, wherein the base platehas an outward facing connection surface configured to position againsta second base plate of the second GRASP mechanism when the first andsecond GRASP mechanisms are docked together;

(b) a two-piece housing unit secured to the base plate over the opening,the two-piece housing unit defined by a lower housing and an upperhousing, the lower housing includes a lip surrounding the opening and aridge extending from the lip to a circular surface wall extending awayfrom the base plate;

(c) a docking nut being positioned against the ridge and over theopening, the docking nut having a threaded interior surface;

(d) a rotational restriction mechanism being positioned against thedocking nut within the circular surface wall to engage the docking nutand configured to permit rotation of the docking nut in a singledirection;

(e) a docking screw threaded into the docking nut, the docking screwhaving an interior channel keyed to receive a drive shaft; and

(f) a motor mechanism configured to rotate the docking screw via thedrive shaft.

Based on the above, the docking screw has a screw length SL configuredto extend through the docking nut and through the base plate when thedocking screw is in an extension position (FIG. 6B) and the docking nuthas a nut length NL configured to define a receiving space 207 (FIG. 9C)below the docking screw 165 when the docking screw is un-extendedthrough the docking nut whereby the receiving space 207 of the dockingnut is further configured to receive a portion of a second docking screwin the extension position when the first and second GRASP mechanisms aredocked together (FIG. 10D).

In various embodiments, the rotational restriction mechanism isconfigured to (i) allow one-way slip rotation of the docking nut whenthe docking screw is fully inserted through the docking nut such that ahead of the docking screw is in contact with the docking nut; and (ii)prevent the counter rotation of the docking nut, such as when thedocking screw is inserted and rotated into the receiving space of asecond GRASP mechanism during a docking of first and second GRASPmechanisms.

The rotational restriction mechanisms can either be employed by a lowerratchet toothed section on the docking nut rotatably and a pawlmechanism positioned to engage the exterior lower ratchet toothedsection to permit rotation of the docking nut in a single direction.Alternatively, the rotational restriction mechanism can be defined byhaving a needle roller clutch positioned in the lower housing andconfigured to permit rotation of the docking nut in a single direction.

In another embodiment, the GRASP mechanism has a base plate with an Xshape and wherein the outward facing connection surface include one ormore alignment probes and one or more alignment indented cones, whereinwhen the first and second GRASP mechanisms are being docked together,the one or more alignment probes are configured to insert and slidewithin corresponding one or more of the alignment indented cones toadjust a position of the first and second GRASP mechanisms.

As provided herein, the GRASP mechanism are typically utilized a part ofa docking system configured to dock two surfaces defined on separatespacecraft. The docking system includes at least a pair of opposingguideless resilient androgynous serial port (GRASP) mechanisms. Each ofthe GRASP mechanisms being positioned on the separate spacecraft andwhich connect to each other to dock the separate spacecraft together.The docking system further includes a mounting platform configured on aside of separate spacecraft, and wherein the sides of the separatespacecraft being configured for docking to each other. Each surface isdesigned to have at least one GRASP mechanism secured to the mountingplatform. The GRASP mechanisms are defined each to include: (i) a baseplate having an opening bored through, wherein the base plate has anoutward facing connection surface configured to position against asecond base plate of the opposing GRASP mechanism when the separatespacecraft are docked together; (ii) a docking nut being positioned overthe opening, the docking nut having a threaded interior surface; (iii) arotational restriction mechanism being positioned against the dockingnut to engage the docking nut and configured to permit rotation of thedocking nut in a single direction; (iv) a docking screw threaded intothe docking nut; (v) a motor mechanism configured to thread the dockingscrew through the docking nut; and (vi) wherein the docking screw has ascrew length configured to extend through the docking nut and throughthe base plate when the docking screw is in an extension position andwherein the docking nut has a nut length configured to define areceiving space below the docking screw when the docking screw isun-extended through the docking nut whereby the receiving space of thedocking nut is further configured to receive a portion of a seconddocking screw in the extension position when the opposing GRASPmechanisms are docking together.

While particular elements, embodiments, and applications of the presentinvention have been shown and described, it is understood that theinvention is not limited thereto because modifications may be made bythose skilled in the art, particularly in light of the foregoingteaching. It is therefore contemplated by the appended claims to coversuch modifications and incorporate those features which come within thespirit and scope of the invention.

We claim:
 1. A guideless resilient androgynous serial port (GRASP)mechanism for use with a secondary docking system for docking twoseparate components together, the GRASP mechanism comprising: a baseplate having an opening bored through, wherein the base plate has anoutward facing connection surface configured to position against thesecondary docking system when the GRASP mechanism and the secondarydocking system are docked together; a two-piece housing unit secured tothe base plate over the opening, the two-piece housing unit defined by alower housing and an upper housing, the lower housing includes a lipsurrounding the opening and a ridge extending from the lip to a circularsurface wall extending away from the base plate, and a channel cut outis further defined along a portion of the circular surface wall; adocking nut being positioned against the ridge and over the opening, thedocking nut having a threaded interior surface and an exterior lowerratchet toothed section rotatably situated within the circular surfacewall of the lower housing; a pawl mechanism being positioned in thechannel cut out and biased to engage the exterior lower ratchet toothedsection to permit rotation of the docking nut in a single direction; adocking screw threaded into the docking nut, the docking screw having aninterior channel keyed to receive a drive shaft; a motor mechanismconfigured to rotate the docking screw via the drive shaft; and whereinthe docking screw has a screw length configured to extend through thedocking nut and through the base plate when the docking screw is in anextension position and wherein the docking nut has a nut lengthconfigured to define a receiving space below the docking screw when thedocking screw is un-extended through the docking nut whereby thereceiving space of the docking nut is further configured to receive aportion of a second docking screw in an extension position when theGRASP mechanism and the secondary docking system are docked together. 2.The GRASP mechanism of claim 1, wherein the base plate of the GRASPmechanism include a plurality of channels bored through and configuredas conduits for signal ports and signal and data pins to provideelectrical and data communications between the GRASP mechanism and thesecondary docking system when secured and connected.
 3. The GRASPmechanism of claim 2, wherein the outward facing connection surface ofthe base plate includes an indented surface surrounding the opening, theindented surface being configured to assist in the alignment when theGRASP mechanism and the secondary docking system are secured together.4. The GRASP mechanism of claim 3, wherein the indented surface has aprofile of a truncated cone tapered towards the opening.
 5. The GRASPmechanism of claim 1, wherein the upper housing being attached to thelower housing to secure the docking nut and pawl mechanism in position,the upper housing includes an upper housing opening sized over thedocking nut to receive the docking screw.
 6. The GRASP mechanism ofclaim 3, wherein the docking screw has a dog end configured to guide thedocking screw into an opening defined on the secondary docking systemwhen the GRASP mechanism and the secondary docking system are positionedtogether.
 7. The GRASP mechanism of claim 1 further comprising, amounting plate opposed to the position of the base plate and wherein atop portion of the drive shaft is rotatably secured thereto.
 8. TheGRASP mechanism of claim 3, wherein the pawl mechanism in combinationwith the lower ratchet toothed section of the docking nut and thedocking screw is configured to: allow one-way slip rotation of thedocking nut when the docking screw is fully inserted through the dockingnut such that a head of the docking screw is in contact with the dockingnut; and prevent the counter rotation of the docking nut, such as whenthe docking screw is inserted and rotated into a receiving space of thesecondary docking system during a docking of the GRASP mechanism and thesecondary docking system.
 9. A guideless resilient androgynous serialport (GRASP) mechanism for a spacecraft docking system and for use witha secondary docking system, wherein the GRASP mechanism comprising: abase plate having an opening bored through, wherein the base plate hasan outward facing connection surface configured to position against thesecondary docking system when the GRASP mechanism and the secondarydocking system are docked together; a two-piece housing unit secured tothe base plate over the opening, the two-piece housing unit defined by alower housing and an upper housing, the lower housing includes a lipsurrounding the opening and a ridge extending from the lip to a circularsurface wall extending away from the base plate; a docking nut beingpositioned against the ridge and over the opening, the docking nuthaving a threaded interior surface; a rotational restriction mechanismbeing positioned against the docking nut within the circular surfacewall to engage the docking nut and configured to permit rotation of thedocking nut in a single direction; a docking screw threaded into thedocking nut, the docking screw having an interior channel keyed toreceive a drive shaft; a motor mechanism configured to rotate thedocking screw via the drive shaft; and wherein the docking screw has ascrew length configured to extend through the docking nut and throughthe base plate when the docking screw is in an extension position andwherein the docking nut has a nut length configured to define areceiving space below the docking screw when the docking screw isun-extended through the docking nut whereby the receiving space of thedocking nut is further configured to receive a portion of a seconddocking screw in the extension position and defined by the secondarydocking system when the GRASP mechanism and the secondary docking systemare docked together.
 10. The GRASP mechanism of claim 9, wherein therotational restriction mechanism is configured to: allow one-way sliprotation of the docking nut when the docking screw is fully insertedthrough the docking nut such that a head of the docking screw is incontact with the docking nut; and prevent the counter rotation of thedocking nut, such as when the docking screw is inserted and rotated intoa receiving space of the secondary docking system during a docking ofthe GRASP mechanism and the secondary docking system.
 11. The GRASPmechanism of claim 9, wherein the docking nut has an exterior lowerratchet toothed section rotatably situated within the circular surfacewall of the lower housing, and wherein the lower housing furtherincludes a channel cut out defined along a portion of the circularsurface wall, and wherein the rotational restriction mechanism isdefined by having a pawl mechanism positioned in the channel cut out andbiased to engage the exterior lower ratchet toothed section to permitrotation of the docking nut in a single direction.
 12. The GRASPmechanism of claim 9, wherein the rotational restriction mechanism isdefined by having a needle roller clutch positioned in the lower housingand configured to permit rotation of the docking nut in a singledirection.
 13. The GRASP mechanism of claim 9, wherein the base plate ofthe GRASP mechanism include a plurality of channels bored through andconfigured as conduits for signal ports and signal and data pins toprovide electrical and data communications between the GRASP mechanismand the secondary docking system when secured and connected.
 14. TheGRASP mechanism of claim 12, wherein the outward facing connectionsurface of the base plate includes an indented surface surrounding theopening, the indented surface being configured to assist in thealignment when the GRASP mechanism and the secondary docking system aresecured together.
 15. The GRASP mechanism of claim 9, wherein theindented surface has a profile of a truncated cone tapered towards theopening.
 16. The GRASP mechanism of claim 9, wherein the docking screwhas a dog end configured to guide the docking screw into an opening ofthe secondary docking system when the GRASP mechanism and the secondarydocking system are positioned together.
 17. The GRASP mechanism of claim9 further comprising, a mounting plate opposed to the position of thebase plate and wherein a top portion of the drive shaft is rotatablysecured thereto.
 18. The GRASP mechanism of claim 9, wherein the baseplate has an X shape and wherein the outward facing connection surfaceinclude one or more alignment probes and one or more alignment indentedcones to match a similar configuration defined on the secondary dockingsystem, wherein when the GRASP mechanism and the secondary dockingsystem are being docked together, the one or more alignment probes areconfigured to insert and slide within corresponding one or more of thealignment indented cones to adjust a position of the GRASP mechanism.19. A primary docking system configured to dock two surfaces, theprimary docking system comprising at one guideless resilient androgynousserial port (GRASP) mechanism for docking with a secondary dockingsystem, wherein the GRASP mechanism and the secondary docking systembeing positioned on separate surfaces and which connect to each other todock the separate surfaces together, the primary docking system furthercomprising: a mounting platform configured on a side of separatespacecraft, wherein the sides of the separate surfaces being configuredfor docking to each other; at least one GRASP mechanism secured to themounting platform of the side of the separate surface, and wherein eachof the GRASP mechanisms including: a base plate having an opening boredthrough, wherein the base plate has an outward facing connection surfaceconfigured to position against a second base plate of the opposingsecondary docking system when the separate surfaces are docked together;a docking nut being positioned over the opening, the docking nut havinga threaded interior surface; a rotational restriction mechanism beingpositioned against the docking nut to engage the docking nut andconfigured to permit rotation of the docking nut in a single direction;a docking screw threaded into the docking nut; a motor mechanismconfigured to thread the docking screw through the docking nut; andwherein the docking screw has a screw length configured to extendthrough the docking nut and through the base plate when the dockingscrew is in an extension position and wherein the docking nut has a nutlength configured to define a receiving space below the docking screwwhen the docking screw is un-extended through the docking nut wherebythe receiving space of the docking nut is further configured to receivea portion of a secondary docking screw defined from the secondarydocking system in the extension position when the primary and secondarydocking systems are docking together.
 20. The primary docking system ofclaim 19, wherein the base plate of each of the GRASP mechanisms has anX shape and wherein the outward facing connection surface include one ormore alignment probes and one or more alignment indented cones, whereinwhen the at least one GRASP mechanism is being docked with the secondarydocking system, the one or more alignment probes are configured toinsert and slide within corresponding one or more of the alignmentindented cones to adjust a position of the primary and secondary dockingsystems.
 21. The primary docking system of claim 20, wherein the outwardfacing connection surface, of the base plate of the at least one GRASPmechanism, includes an indented surface surrounding the opening, theindented surface being configured to assist in the alignment when theseparate surfaces dock.
 22. The primary docking system of claim 19,wherein the docking nut has an exterior lower ratchet toothed sectionrotatably situated within the circular surface wall of the lowerhousing, and wherein the lower housing further includes a channel cutout defined along a portion of the circular surface wall, and whereinthe rotational restriction mechanism is defined by having a pawlmechanism positioned in the channel cut out and biased to engage theexterior lower ratchet toothed section to permit rotation of the dockingnut in a single direction.
 23. The primary docking system of claim 19,wherein the rotational restriction mechanism is defined by having aneedle roller clutch positioned in the lower housing and configured topermit rotation of the docking nut in a single direction.